Academic literature on the topic 'XO sex-chromosome system'

Most nematodes have XO male/XX female sex determination. C. elegans is anomalous, having XX hermaphrodites rather than females. The hermaphrodite condition appears to result from the modification of a basic male/female sex-determination system, which permits both spermatogenesis and oogenesis to occur within a female soma. This modification is achieved by a germ-line-specific control acting at one step in a cascade of autosomal regulatory genes, which respond to X-chromosome dosage and direct male, female, or hermaphrodite development. Mutations of one of these genes can be used to construct artificial strains with ZZ male/WZ female sex determination. Primary sex determination normally depends on the ratio of X chromosomes to autosomes, as in Drosophila, and there appear to be multiple sites on the X chromosome that contribute to this ratio. Also, as in Drosophila, X-chromosome expression is compensated to equalize gene activity in XX and XO animals. Interactions between dosage compensation and sex determination are described and discussed.

Data on ten intersexual marsupials, eight of which were of known karyotype, are presented and reviewed. Three of the intersexes were known or suspected XO/XX or XO/XX/XXX, two were XXY, one was XXY/XY/XX and two were XY in sex chromosome constitution. In all three intersexes which had an XO cell line, but in which no Y chromosome was found in any cell, a small empty scrotum was found to one side of the midline or in the midline. Those which had a non-midline scrotum had mammary tissue on the opposite side and a partial or complete pouch. The intersex with the midline scrotum had no pouch or mammary glands. Unilateral or bilateral putative spermatic cords, not containing a ductus deferens, descended to the scrotum, but in all other respects the internal reproductive systems were like those of normal XX female marsupials. Intersexes with no Y chromosome were of female body size when adult. The XXY and XXY/XY/XX intersexes all had complete pouches and mammary glands and none had a scrotum. All had well developed male internal reproductive systems and undescended testis-like gonads, and were of intermediate body size. Both XY intersexes also had complete pouches and mammary glands, no scrotum, and male-type internal reproductive systems with undescended testes which were normal except for absence of post- primary spermatocyte stages of spermatogenesis. One XY intersex was fully adult and it did not differ from normal XY males of the same species in body measurements, body weight and secondary sex coloration. One of the intersexes of unknown karyotype, but of suspected XX chromosome constitution, was morphologically like the XO/XX/XXX mosaic with a centrally placed scrotum. The other, of suspected XY chromosome constitution, was essentially comparable to the XY intersexes. The data are interpreted, at the whole chromosome level, as follows. In the presence of a single active X chromosome scrotal and spermatic cord development were initiated, whereas they were inhibited in the presence of two X chromosomes. Complete scrotal development completely inhibited, and unilateral scrotal development partly inhibited, pouch and mammary gland development. The Y chromosome was responsible for primary gonadal sex and, apparently through production of MIS, eliminated the Miillerian (i.e. female) sex ducts. Development of a male type of reproductive system was dependent on presence of a Y chromosome and, apparently, androgen production from testes or testis-like gonads. At the gene level the data may be interpreted in terms of a hypothetical S or 'switch' locus, carried on the X chromosome, which induced scrotal development in single dose and a pouch and mammary glands in double dose. If this hypothesis is correct, it would explain the occurrence of incomplete X-chromosome inactivation in marsupials; complete X-inactivation is impossible in marsupials because it would leave each female with a scrotum, not a pouch.

Abstract The natural sexes of the nematode Caenorhabditis elegans are the self-fertilizing hermaphrodite (XX) and the male (XO). The underlying genetic pathway controlling sexual phenotype has been extensively investigated. Mutations in key regulatory genes have been used to create a series of stable populations in which sex is determined not by X chromosome dosage, but in a variety of other ways, many of which mimic the diverse sex-determination systems found in different animal species. Most of these artificial strains have male and female sexes. Each of seven autosomal genes can be made to adopt a role as the primary determinant of sex, and each of the five autosomes can carry the primary determinant, thereby becoming a sex chromosome. Strains with sex determination by fragment chromosomes, episomes, compound chromosomes, or environmental factors have also been constructed. The creation of these strains demonstrates the ease with which one sex-determination system can be transformed into another.

Abstract The parasitic nematode Strongyloides ratti reproduces by both parthenogenesis and sexual reproduction, but its genetics are poorly understood. Cytological evidence suggests that sex determination is an XX/XO system. To investigate this genetically, we isolated a number of sex-linked DNA markers. One of these markers, Sr-mvP1, was shown to be single copy and present at a higher dose in free-living females than in free-living males. The inheritance of two alleles of Sr-mvP1 by RFLP analysis was consistent with XX female and XO male genotypes. Analysis of the results of sexual reproduction demonstrated that all progeny inherit the single paternal X chromosome and one of the two maternal X chromosomes. Therefore, all stages of the S. ratti life cycle, with the exception of the free-living males, are XX and genetically female. These findings are considered in relation to previous analyses of S. ratti and to other known sex determination systems.

The male adults of four species of the Chinese Panorpidae in Mecoptera were cytogenetically studied using conventional squashing procedures. The results show that their sex-chromosome system belongs to the XO type, with <i>n</i> = 19 + X(O) in <i>Panorpa emarginata</i> Cheng, 1949 and <i>Panorpa dubia</i> Chou &amp; Wang, 1981, <i>n</i> = 23 + X(O) in <i>Panorpa </i>sp<i>.</i>, and <i>n</i> = 20 + X(O) in <i>Neopanorpa lui</i> Chou &amp; Ran, 1981<i>.</i> X chromosomes of these species usually appear dot-shaped in late prophase I and are easily differentiated from autosomal bivalents. Meiosis in these Panorpidae lacks typical diplotene and diakinesis. In late prophase I, pairs of homologous chromosomes remain parallel in a line and show no evidence of crossing-over. Some of them even appear as a single unit because of extremely intimate association, all with a tendency of increasing condensation. The evolutionary significance of their chromosomal differences and the achiasmatic meiosis of Panorpidae are briefly discussed.

SUMMARYParasitic lifestyles evolved many times independently. Just within the phylum Nematoda animal parasitism must have arisen at least four times. Switching to a parasitic lifestyle is expected to lead to changes in various life history traits including reproductive strategies. Parasitic nematode worms of the genus Strongyloides represent an interesting example to study these processes because they are still capable of forming facultative free-living generations in between parasitic ones. The parasitic generation consists of females only, which reproduce parthenogenetically. The sex in the progeny of the parasitic worms is determined by environmental cues, which control a, presumably ancestral, XX/XO chromosomal sex determining system. In some species the X chromosome is fused with an autosome and one copy of the X-derived sequences is removed by sex-specific chromatin diminution in males. Here I propose a hypothesis for how today's Strongyloides sp. might have evolved from a sexual free-living ancestor through dauer larvae forming free-living and facultative parasitic intermediate stages.